Joyce E. Fry

Genetic Transformation of Wheat Mediated by Agrobacterium tumefaciens

A rapid Agrobacterium tumefaciens-mediated transformation system for wheat was developed using freshly isolated immature embryos, precultured immature embryos, and embryogenic calli as explants. The explants were inoculated with a disarmed A. tumefaciens strain C58 (ABI) harboring the binary vector pMON18365 containing the [beta]-glucuronidase gene with an intron, and a selectable marker, the neomycin phosphotransferase II gene. Various factors were found to influence the transfer-DNA delivery efficiency, such as explant tissue and surfactants present in the inoculation medium. The inoculated immature embryos or embryogenic calli were selected on G418-containing media. Transgenic plants were regenerated from all three types of explants. The total time required from inoculation to the establishment of plants in soil was 2.5 to 3 months. So far, more than 100 transgenic events have been produced. Almost all transformants were morphologically normal. Stable integration, expression, and inheritance of the transgenes were confirmed by molecular and genetic analysis. One to five copies of the transgene were integrated into the wheat genome without rearrangement. Approximately 35% of the transgenic plants received a single copy of the transgenes based on Southern analysis of 26 events. Transgenes in T1 progeny segregated in a Mendelian fashion in most of the transgenic plants.

Leaf disc transformation of cultivated tomato (L. esculentum) using Agrobacterium tumefaciens.

The leaf disc transformation/regeneration system was modified for tomato (L. esculentum). Both leaf explants and cotyledon/hypocotyl sections can be used to regenerate transformed plants. We have obtained over 300 transgenic plants from eight tomato cultivars. We have evidence for both single and multi-copy insertions of the T-DNA, and have demonstrated inheritance of the T-DNA insert in the expected Mendelian ratios. Several heterologous promoters function in tomato. A reduced efficiency of transformation was observed with binary T-DNA vectors as compared to co-integrate T-DNA vectors. The ease of the leaf disc method makes tomato a premier experimental organism for plant biotechnology.

Leaf disc transformation

Leaf disc transformation of tobacco is the paradigm for Agrobacterium-mediated transformation of plant tissues and subsequent selection and regeneration of transgenic plants. This system permits efficient gene transfer, selection and regeneration to be coupled together in a simple process. Tobacco is an excellent host for A. tumefaciens, and also responds exceedingly well in culture. While the technique is most easily practiced with tobacco, it has been applied to a number of other species (Table 1). This example will be described for tobacco, using a vector that confers kanamycin resistance, pMON200 [5].

An Improved Green Fluorescent Protein Gene as a Vital Marker in Plants

A synthetic green fluorescent protein (GFP) gene (pgfp) was constructed to improve GFP expression in plants. Corn and tobacco protoplast transient assays showed that pgfp gave about 20-fold brighter fluorescence than the wild-type gene (gfp). Replacement of the serine at position 65 with a threonine (S65Tpgfp) or a cysteine (S65Cpgfp) yielded 100- to 120-fold brighter fluorescence than wild-type gfp upon excitation with 490-nm light. Incorporation of a plant intron into the coding region yielded an additional 1.4-fold improvement, for a cumulative improvement of about 150-fold in fluorescence at 490-nm excitation. Various versions of pgfp were also stably introduced into corn, wheat, tobacco, and Arabidopsis plants. Bright-green fluorescence was observed with a fluorescence microscope in virtually all examined tissues of transgenic monocots and dicots. In the case of Arabidopsis, expression of the pgfp gene under the enhanced 35S promoter of the cauliflower mosaic virus produced green fluorescence that was readily detectable by eye using a hand-held, long-wave ultraviolet lamp and/or a black-light source.

Transformation of Brassica napus with Agrobacterium tumefaciens based vectors.

A reproducible system to produce transgenic Brassica napus plants has been developed using stem segments. Stem segments from 6–7 week old plants were inoculated with an Agrobacterium tumefaciens strain containing a disarmed tumor-inducing plasmid pTiT37-SE carrying a chimeric bacterial gene encoding kanamycin resistance (pMON200). Stem explants were cocultured for 2 days before transfer to kanamycin selection medium. Shoots regenerated directly from the explant in 3–6 weeks and were excised, dipped in Rootone®, and rooted in soil. Transformation was confirmed by opine production, kanamycin resistance, and DNA blot hybridization in the primary transformants. Final proof of transformation was demonstrated by the co-transfer of opine production and kanamycin resistance to progeny in a Mendelian fashion. Over 200 transgenic Brassica napus plants have been produced using this system.

Glyphosate-tolerant CP4 and GOX genes as a selectable marker in wheat transformation

The lack of alternative selectable markers in crop transformation has been a substantial barrier for commercial application of agricultural biotechnology. We have developed an efficient selection system for wheat transformation using glyphosate-tolerant CP4 and GOX genes as a selectable marker. Immature embryos of the wheat cultivar Bobwhite were bombarded with two separate plasmids harboring the CP4/GOX and GUS genes. After a 1 week delay, the bombarded embryos were transferred to a selection medium containing 2 mM glyphosate. Embryo-derived calli were subcultured onto the same selection medium every 3 weeks consecutively for 9–12 weeks, and were then regenerated and rooted on selection media with lower glyphosate concentrations. Transgenic plants tolerant to glyphosate were recovered. ELISA assay confirmed expression of the CP4 and GOX genes in R0 plants. Southern blot analysis demonstrated that the transgenes were integrated into the wheat genomes and transmitted to the following generation. The use of CP4 and GOX genes as a selectable marker provides an efficient, effective, and alternative transformation selection system for wheat.

DESICCATION OF PLANT TISSUES POST-AGROBACTERIUM INFECTION ENHANCES T-DNA DELIVERY AND INCREASES STABLE TRANSFORMATION EFFICIENCY IN WHEAT

SummaryFactors influencing the Agrobacterium-mediated transformation of both monocotyledonous and dicotyledonous plant species have been widely investigated. These factors include manipulating Agrobacterium strains and plasmids, growth conditions for vir gene induction, plant genotype, inoculation and co-culture conditions, and the selection agents and their application regime. We report here a novel physical parameter during co-culture, desiccation of plant cells or tissues post-Agrobacterium infection, which greatly enhances transfer DNA (T-DNA) delivery and increases stable transformation efficiency in wheat. Desiccation during co-culture dramatically suppressed Agrobacterium growth, which is one of the factors known to favor plant cell recovery. Osmotic and abscisic acid treatments and desiccation prior to inoculation did not have the same enhancement effect as desiccation during co-culture on T-DNA delivery in wheat. An efficient transformation protocol has been developed based on desiccation and is suitable for both paromomycin and glyphosate selection. Southern analysis showed approximately 67% of transgenic wheat plants received a single copy of the transgene.

Lipoic acid—an unique plant transformation enhancer

Including lipoic acid (LA) in culture media during Agrobacterium transformation processes of four crop species has significantly improved the transformation methods of the crops, even for previously recalcitrant genotypes. Plant transformation efficiency of soybean was significantly increased from 0.6% to 3.7% and tomato from 29.8% to 87.0%. Transformation efficiency was doubled from 2.8% to 5.7% in wheat. The frequency of glyphosate-resistant embryos had a significant increase from 41.4% to 61.2% in cotton. Regeneration of non-transgenic shoots under selection (“shoot escapes”) was significantly reduced in tomato from 91.5% to 46.2% while in soybean from 92.0% to 72.0% under optimal conditions. This study also demonstrated that the increase of transformation efficiency in tomato was accompanied by as much as a significant 2-fold reduction in severity of browning of Agrobacterium-infected plant tissues and up to a significant 3-fold increase in the percentage of explants with a high level of transient gene expression. LA application in plant transformation has enabled the resolution of three common problems in plant transformation: browning or necrosis of the transformed cells or tissues, difficulty in regenerating transformed cells or tissues, and shoot escapes, which severely limit the number of transgenic plants that can be regenerated.